JP2005210088A - Cooling device in closed cabinet - Google Patents
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- JP2005210088A JP2005210088A JP2004362444A JP2004362444A JP2005210088A JP 2005210088 A JP2005210088 A JP 2005210088A JP 2004362444 A JP2004362444 A JP 2004362444A JP 2004362444 A JP2004362444 A JP 2004362444A JP 2005210088 A JP2005210088 A JP 2005210088A
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この発明は、密閉された筐体内を冷却する装置に関し、さらに詳しくは、たとえば携帯電話や自動車電話などの移動無線電話の無線中継装置が設置された密閉筐体内を冷却する装置に関する。 The present invention relates to a device that cools the inside of a sealed housing, and more particularly, to a device that cools the inside of a sealed housing in which a wireless relay device of a mobile wireless telephone such as a mobile phone or a car phone is installed.
たとえば、携帯電話や自動車電話などの移動無線電話の無線中継装置の場合、密閉された筐体内に数々の発熱電子部品が配置されるため、これらの発熱電子部品を冷却する必要がある。ところが、このような発熱電子部品に水分、埃、煤塵などが付着すると、その性能が低下したり、あるいは破損したりすることがあるので、密閉筐体内に筐体外空気を取り入れてその内部を冷却することはできない。 For example, in the case of a wireless relay device for a mobile radio telephone such as a mobile phone or a car phone, a large number of heat generating electronic components are arranged in a hermetically sealed casing. Therefore, it is necessary to cool these heat generating electronic components. However, if moisture, dust, dust, etc. adhere to such heat-generating electronic components, its performance may be degraded or damaged, so air outside the case is taken into the sealed case to cool the inside. I can't do it.
そこで、密閉筐体と、筐体内の空気と筐体外の空気とを熱交換させる熱交換装置とを備えた密閉筐体内冷却装置が種々提案されている。 In view of this, various types of sealed casing cooling devices have been proposed that include a sealed casing and a heat exchange device that exchanges heat between the air inside the casing and the air outside the casing.
たとえば、密閉筐体、密閉筐体内に一体に設けられたケーシング、ケーシング内を筐体内空気通路としての高温側伝熱空間と筐体外空気通路としての低温側伝熱空間とに分離する流体隔離板、高温側伝熱空間の熱を低温側伝熱空間へ移動させることにより密閉筐体内の空気温度を上限温度以下にする沸騰冷却装置、低温側伝熱空間において低温の筐体外空気の空気流を発生させる2個の上部側送風機、高温側伝熱空間において高温の筐体内空気の空気流を発生させる2個の下部側送風機、ならびに上部側および下部側送風機の通電制御をするコントローラから構成されているものが知られている(特許文献1参照)。 For example, a sealed housing, a casing integrally provided in the sealed housing, and a fluid separator that separates the inside of the casing into a high temperature side heat transfer space as an air passage inside the housing and a low temperature side heat transfer space as an air passage outside the housing Boiling cooling device that lowers the air temperature in the sealed casing to the upper limit temperature or less by moving the heat in the high temperature side heat transfer space to the low temperature side heat transfer space, the air flow of the low temperature outside the case in the low temperature side heat transfer space Two upper fans to be generated, two lower fans to generate an air flow of high-temperature housing air in the high-temperature side heat transfer space, and a controller that controls energization of the upper and lower fans. Is known (see Patent Document 1).
ところで、特許文献1記載の冷却装置の冷却性能を向上させるためには、筐体を大型化したり、沸騰冷却装置を大型化したり、送風機の能力を高めたりする必要がある。しかしながら、上述したような無線中継装置の場合、設置スペースに制約があり、筐体や沸騰冷却装置の大型化には限界がある。また、送風機の能力を高めると消費電力が多くなるので、運転コストが高くなる。
この発明の目的は、上記問題を解決し、全体の小型化を図ることができるとともに、運転コストを安くすることができる密閉筐体内冷却装置を提供することにある。 An object of the present invention is to provide a hermetically sealed in-chamber cooling device that can solve the above-described problems, reduce the overall size, and reduce the operating cost.
1)密閉された筐体内を冷却する装置であって、密閉筐体と、互いに独立した筐体内空気通路および筐体外空気通路を有し、かつ筐体内の空気と筐体外の空気とを熱交換させる熱交換装置と、筐体外に配置された太陽光発電パネルと、太陽光発電パネルで得られた電力を利用して筐体内を冷却する冷却手段とを備えている密閉筐体内冷却装置。 1) A device that cools the inside of a sealed housing, has a sealed housing, and an air passage inside the housing and an air passage outside the housing, and exchanges heat between the air inside the housing and the air outside the housing. A sealed in-case cooling device comprising: a heat exchanging device, a solar power generation panel arranged outside the case, and a cooling means for cooling the inside of the case using electric power obtained by the solar power generation panel.
2)熱交換装置が、ケーシングと、ケーシング内に配置された熱交換器と、筐体内の空気をケーシング内に取り入れて熱交換器を通過させた後筐体内に戻す筐体内空気送風機と、筐体外の空気をケーシング内に取り入れて熱交換器を通過させた後筐体外に戻す筐体外空気送風機とを備えており、ケーシングに、筐体内に通じる筐体内空気入口および筐体内空気出口と、筐体外に通じる筐体外空気入口および筐体外空気出口とが形成され、熱交換器が、筐体内空気入口および筐体内空気出口と通じる筐体内空気通路と、筐体外空気入口および筐体外空気出口と通じかつ筐体内空気通路と独立した筐体外空気通路とを有し、筐体内空気通路および筐体外空気通路にそれぞれインナーフィンが配置されている上記1)記載の密閉筐体内冷却装置。 2) The heat exchange device includes a casing, a heat exchanger disposed in the casing, an air blower in the casing that takes air in the casing into the casing, passes the heat exchanger, and returns the casing to the casing, An outside air blower that takes outside air into the casing and passes it through the heat exchanger and returns it outside the housing, and the casing has an air inlet and air outlet inside the housing that communicates with the inside of the housing, and a housing. An external air inlet and an external air outlet that communicate with the outside of the body are formed, and the heat exchanger communicates with the internal air passage that communicates with the internal air inlet and the internal air outlet, and the external air inlet and the external air outlet. The sealed in-chamber cooling device according to 1), further including an air passage outside the housing and an air passage outside the housing, wherein inner fins are arranged in the air passage inside the housing and the air passage outside the housing, respectively.
3)熱交換器の筐体内空気通路および筐体外空気通路がそれぞれ上下方向に伸びており、筐体内空気入口および筐体外空気出口がそれぞれケーシングの上部に形成され、筐体内空気出口および筐体外空気入口がそれぞれケーシングの下部に形成されている上記2)記載の密閉筐体内冷却装置。 3) The inside air passage and the outside air passage of the heat exchanger extend in the vertical direction, and the inside air inlet and the outside air outlet are formed at the upper part of the casing, respectively. The airtight casing cooling device according to 2) above, wherein the inlets are respectively formed in the lower part of the casing.
4)熱交換器が、相互に間隔をおいて並列状に配置された複数の縦長方形状平板と、隣り合う平板間の間隙の下端開口を1つおきに閉鎖する下閉鎖部材と、隣り合う平板間の間隙のうち下端開口が閉鎖されていない間隙の上端開口を閉鎖する上閉鎖部材と、隣り合う平板間の間隙のうち下端開口が閉鎖された間隙における筐体内側への開口を、下端部を除いて閉鎖する第1内側閉鎖部材と、隣り合う平板間の間隙のうち下端開口が閉鎖された間隙における筐体外側への開口全体を閉鎖する第1外側閉鎖部材と、隣り合う平板間の間隙のうち上端開口が閉鎖された間隙における筐体外側への開口を、上端部を除いて閉鎖する第2外側閉鎖部材と、隣り合う平板間の間隙のうち上端開口が閉鎖された間隙における筐体内側への開口全体を閉鎖する第2内側閉鎖部材と、隣り合う平板間の間隙に配置されたインナーフィンとを備えており、隣り合う2枚の平板、下閉鎖部材、第1内側閉鎖部材および第1外側閉鎖部材により筐体内空気通路が形成され、隣り合う2枚の平板、上閉鎖部材、第2外側閉鎖部材および第2内側閉鎖部材により筐体外空気通路が形成されている上記2)または3)記載の密閉筐体内冷却装置。 4) The heat exchanger is adjacent to a plurality of vertical rectangular flat plates arranged in parallel at intervals, and a lower closing member for closing every other lower end opening of the gap between adjacent flat plates. An upper closing member for closing the upper end opening of the gap between the flat plates where the lower end opening is not closed, and an opening to the inside of the housing in the gap between the adjacent flat plates where the lower end opening is closed, A first inner closing member that closes except for a portion, a first outer closing member that closes the entire opening to the outside of the housing in a gap in which a lower end opening is closed among gaps between adjacent flat plates, and between adjacent flat plates In the gap between the adjacent flat plates, the second outer closing member that closes the opening to the outside of the housing in the gap in which the upper end opening is closed, and the gap between the adjacent flat plates in the gap in which the upper end opening is closed. Close the entire opening to the inside of the housing An inner closing member and an inner fin disposed in a gap between adjacent flat plates, and an air passage in the housing by the two adjacent flat plates, the lower closing member, the first inner closing member, and the first outer closing member. 2) or 3), wherein the outside air passage is formed by two adjacent flat plates, an upper closing member, a second outer closing member, and a second inner closing member.
5)熱交換器が、相互に間隔をおいて並列状に配置された複数の縦長方形状平板部と、隣り合う平板部の筐体内側縁部どうしおよび筐体外側縁部どうしを交互に一体に連結する連結板部とよりなり、かつ筐体内側に開口した第1の間隙と筐体外側に開口した第2の間隙とを交互に有する蛇行板、蛇行板の筐体内側および筐体外側を向いた面をそれぞれ全体に覆う内外両閉鎖板、蛇行板の第1間隙の下端開口を閉鎖する下閉鎖部材、蛇行板の第2間隙の上端開口を閉鎖する上閉鎖部材、ならびに蛇行板の第1および第2間隙に配置されたインナーフィンを備えており、内側閉鎖板における蛇行板の第1間隙と対応する部分の下端部に開口が形成され、外側閉鎖板における蛇行板の第2間隙と対応する部分の上端部に開口が形成され、蛇行板の第1間隙を形成する隣り合う2つの平板部、これら2つの平板部の筐体外側縁部どうしを一体に連結する連結板部、内側閉鎖板および下閉鎖部材により筐体内空気通路が形成され、蛇行板の第2間隙を形成する隣り合う2つの平板部、これら2つの平板部の筐体内側縁部どうしを一体に連結する連結板部、外側閉鎖板および上閉鎖部材により筐体外空気通路が形成されている上記2)または3)記載の密閉筐体内冷却装置。 5) A heat exchanger alternately integrates a plurality of vertical rectangular flat plate portions arranged in parallel at intervals, and the case inner edges and case outer edges of adjacent plate portions. And a meander plate having a first gap opened inside the casing and a second gap opened outside the casing, the casing inner side of the meander plate and the casing outer side. Both inner and outer closing plates covering the surfaces facing each other, a lower closing member for closing the lower end opening of the first gap of the meandering plate, an upper closing member for closing the upper end opening of the second gap of the meandering plate, and the serpentine plate Inner fins arranged in the first and second gaps are provided, an opening is formed at the lower end portion of the inner closing plate corresponding to the first gap of the meandering plate, and the second gap of the meandering plate in the outer closing plate And an opening is formed at the upper end of the portion corresponding to the first portion of the meandering plate. An air passage in the housing is formed by two adjacent flat plate portions that form a gap, a connecting plate portion that integrally connects the outer side edge portions of the two flat plate portions, an inner closing plate, and a lower closing member. An air passage outside the housing is formed by two adjacent flat plate portions that form the second gap, a connecting plate portion that integrally connects the case inner edges of the two flat plate portions, an outer closing plate, and an upper closing member. The sealed internal cooling device according to 2) or 3) above.
6)冷却手段が、筐体の内外に跨るように配置されかつ筐体の内外で冷却流体を循環させる冷却流体循環管と、筐体外に配置されかつ冷却流体循環管内で冷却流体を循環させるポンプとを備えており、冷却流体循環管における筐体内に存在する部分に受熱部が設けられるとともに筐体外に存在する部分に放熱部が設けられ、ポンプが、太陽光発電パネルで得られた電力により駆動される上記1)〜5)のうちのいずれかに記載の密閉筐体内冷却装置。 6) A cooling fluid circulation pipe in which the cooling means is arranged so as to straddle the inside and outside of the casing and the cooling fluid is circulated inside and outside of the casing, and a pump which is arranged outside the casing and circulates the cooling fluid in the cooling fluid circulation pipe The cooling fluid circulation pipe is provided with a heat receiving portion in a portion existing in the housing and a heat radiating portion is provided in a portion existing outside the housing, and the pump is driven by electric power obtained from the photovoltaic power generation panel. The airtight casing cooling device according to any one of 1) to 5), which is driven.
7)冷却流体循環管の受熱部が、熱交換装置における筐体内空気通路の入口付近に配されている上記6)記載の密閉筐体内冷却装置。 7) The closed casing cooling device according to 6) above, wherein the heat receiving part of the cooling fluid circulation pipe is arranged near the inlet of the casing internal air passage in the heat exchange apparatus.
8)冷却流体循環管の受熱部の周囲に受熱フィンが設けられ、同じく放熱部の周囲に放熱フィンが取り付けられている上記6)または7)記載の密閉筐体内冷却装置。 8) The cooling device in the sealed casing according to 6) or 7) above, wherein heat receiving fins are provided around the heat receiving part of the cooling fluid circulation pipe, and heat radiating fins are also attached around the heat radiating part.
9)筐体外に、冷却流体循環管の放熱フィンに風を送る送風機が配置され、送風機が太陽光発電パネルで得られる電力により駆動される上記8)記載の密閉筐体内冷却装置。 9) The cooling device in the hermetically sealed casing according to 8), wherein a blower for sending wind to the heat dissipating fins of the cooling fluid circulation pipe is disposed outside the casing, and the blower is driven by electric power obtained from the photovoltaic power generation panel.
10)冷却手段が、筐体の内外に跨るように配置された複数のヒートパイプと、ヒートパイプにおける筐体外に存在する部分に風を送る送風機とを備えており、ヒートパイプにおける筐体内に存在する部分に蒸発部が設けられるとともに筐体外に存在する部分に凝縮部が設けられ、送風機が、太陽光発電パネルで得られた電力により駆動される上記1)〜5)のうちのいずれかに記載の密閉筐体内冷却装置。 10) The cooling means includes a plurality of heat pipes arranged so as to straddle the inside and outside of the casing, and a blower that sends air to a portion of the heat pipe that exists outside the casing, and exists in the casing of the heat pipe. In any one of the above 1) to 5), the evaporation unit is provided in the part to be provided and the condensing part is provided in the part existing outside the housing, and the blower is driven by the electric power obtained by the photovoltaic power generation panel. The cooling device in a sealed casing as described.
11)ヒートパイプの蒸発部が、熱交換装置における筐体内空気通路の入口付近に配されている上記10)記載の密閉筐体内冷却装置。 11) The hermetically sealed internal casing cooling device according to 10) above, wherein an evaporation portion of the heat pipe is disposed in the vicinity of the inlet of the internal air passage in the heat exchange apparatus.
12)ヒートパイプの蒸発部の周囲に受熱フィンが設けられ、同じく凝縮部の周囲に放熱フィンが取り付けられており、放熱フィンに、送風機により風が送られる上記10)または11)記載の密閉筐体内冷却装置。 12) A heat receiving fin is provided around the evaporation part of the heat pipe, and a heat radiating fin is also attached around the condensing part, and air is sent to the heat radiating fin by a blower, as described in 10) or 11) above. Body cooling device.
13)筐体の外面全体に白色塗膜が形成されている上記1)〜12)のうちのいずれかに記載の密閉筐体内冷却装置。 13) The airtight casing cooling device according to any one of 1) to 12) above, wherein a white coating film is formed on the entire outer surface of the casing.
14)密閉筐体内に発熱電子部品が配置されている上記1)〜13)のうちのいずれかに記載の密閉筐体内冷却装置。 14) The cooling device in a sealed casing according to any one of 1) to 13) above, wherein a heat generating electronic component is disposed in the sealed casing.
15)上記1)〜13)のうちのいずれかに記載された密閉筐体内冷却装置の密閉筐体が、ハウジングとして用いられている移動無線電話用無線中継装置。 15) A radio relay device for a mobile radio telephone in which the sealed casing of the cooling apparatus in the sealed casing described in any one of 1) to 13) above is used as a housing.
上記1)の密閉筐体内冷却装置によれば、熱交換装置の他に、筐体外に配置された太陽光発電パネルと、太陽光発電パネルで得られた電力を利用して筐体内を冷却する冷却手段とを備えているので、筐体および熱交換装置を大型化することなく、筐体内の冷却効率を向上させることができる。したがって、全体の小型化を図ることが可能になる。また、冷却手段は、太陽光発電パネルで得られた電力を利用して筐体内を冷却するので、運転コストが安くなる。なお、太陽光発電パネルの発電効率は夜間や冬期には低下するが、夜間や冬期においては筐体外の温度も低くなるので、筐体内の温度も低下し、熱交換装置だけによっても筐体内を十分に冷却することができる。 According to the airtight casing cooling device of 1) above, the inside of the casing is cooled using the solar power generation panel arranged outside the casing and the electric power obtained by the solar power generation panel in addition to the heat exchange device. Since the cooling means is provided, the cooling efficiency in the housing can be improved without increasing the size of the housing and the heat exchange device. Therefore, it is possible to reduce the overall size. Moreover, since the cooling means cools the inside of the housing using the electric power obtained by the photovoltaic power generation panel, the operating cost is reduced. Note that the power generation efficiency of the photovoltaic power generation panel decreases at night and in winter, but the temperature outside the case also decreases at night and in winter, so the temperature inside the case also decreases, and only the heat exchange device can It can be cooled sufficiently.
上記2)の密閉筐体内冷却装置によれば、熱交換装置の構成が比較的簡単になる。 According to the airtight case cooling device 2), the configuration of the heat exchange device is relatively simple.
上記3)の密閉筐体内冷却装置によれば、筐体内空気は筐体内空気通路を下向きに流れ、筐体外空気は筐体外空気通路を上向きに流れるので両者は対向流となり、熱交換器での熱交換効率が向上する。 According to the airtight housing cooling device of 3) above, the air in the housing flows downward in the air passage in the housing and the air outside the housing flows upward in the air passage outside the housing, so that both flow in opposite directions, and in the heat exchanger Heat exchange efficiency is improved.
上記4)および5)の密閉筐体内冷却装置によれば、熱交換装置の熱交換器の構成が比較的簡単になる。 According to the sealed case cooling devices 4) and 5) above, the configuration of the heat exchanger of the heat exchange device becomes relatively simple.
上記6)の密閉筐体内冷却装置によれば、太陽光発電パネルで得られた電力によりポンプを駆動し、ポンプにより冷却流体循環管内で冷却流体を循環させることによって、筐体内を冷却することができる。 According to the airtight casing cooling device of 6) above, the pump is driven by the electric power obtained by the photovoltaic power generation panel, and the cooling fluid is circulated in the cooling fluid circulation pipe by the pump, thereby cooling the inside of the casing. it can.
上記7)の密閉筐体内冷却装置によれば、冷却流体循環管内を循環する冷却流体により冷却された筐体内空気が、熱交換装置の筐体内空気通路内に流入し、熱交換装置においてさらに冷却されるので、筐体内の冷却効率が向上する。 According to the hermetically sealed cooling device in 7) above, the air in the housing cooled by the cooling fluid circulating in the cooling fluid circulation pipe flows into the air passage in the housing of the heat exchange device, and is further cooled in the heat exchange device. Therefore, the cooling efficiency in the housing is improved.
上記8)の密閉筐体内冷却装置によれば、冷却流体循環管による筐体内空気の冷却効率が一層向上する。 According to the airtight casing cooling device of 8), the cooling efficiency of the air in the casing by the cooling fluid circulation pipe is further improved.
上記9)の密閉筐体内冷却装置によれば、冷却流体循環管による筐体内空気の冷却効率が一層向上する。 According to the airtight casing cooling device of the above 9), the cooling efficiency of the air in the casing by the cooling fluid circulation pipe is further improved.
上記10)の密閉筐体内冷却装置によれば、ヒートパイプの蒸発部において作動液が筐体空気内の熱を受けて蒸発して凝縮部に流れ、ここで送風機により送られる空気に放熱して凝縮し、蒸発部に戻る。このようなサイクルを繰り返すことにより、筐体内が冷却される。 According to the airtight case cooling device of 10) above, the working fluid receives heat in the case air and evaporates in the evaporation part of the heat pipe and flows to the condensation part, where it dissipates heat to the air sent by the blower. Condensates and returns to the evaporation section. By repeating such a cycle, the inside of the housing is cooled.
上記11)の密閉筐体内冷却装置によれば、ヒートパイプにより冷却された筐体内空気が、熱交換装置の筐体内空気通路内に流入し、熱交換装置においてさらに冷却されるので、筐体内の冷却効率が向上する。 According to the airtight casing cooling device of 11) above, the air in the casing cooled by the heat pipe flows into the air passage in the casing of the heat exchange device and is further cooled in the heat exchange device. Cooling efficiency is improved.
上記12)の密閉筐体内冷却装置によれば、ヒートパイプによる筐体内空気の冷却効率が一層向上する。 According to the above-mentioned sealed casing cooling device 12), the cooling efficiency of the casing air by the heat pipe is further improved.
上記13)の密閉筐体内冷却装置によれば、筐体への太陽光の吸収が抑制されるので、筐体内空気の温度上昇が抑制され、その結果熱交換装置および冷却手段による筐体内の冷却効率が向上する。 According to the airtight casing cooling device of 13) above, the absorption of sunlight into the casing is suppressed, so that the temperature rise in the casing air is suppressed. As a result, the cooling of the casing by the heat exchange device and the cooling means is performed. Efficiency is improved.
以下、この発明の実施形態を、図面を参照して説明する。なお、この実施形態は、この発明による冷却装置を携帯電話の無線中継装置に適用したものである。全図面を通じて同一部分および同一物には同一符号を付して重複する説明を省略する。 Embodiments of the present invention will be described below with reference to the drawings. In this embodiment, the cooling device according to the present invention is applied to a wireless relay device of a mobile phone. Throughout the drawings, the same parts and the same parts are denoted by the same reference numerals, and redundant description is omitted.
以下の説明において、「アルミニウム」という用語には、純アルミニウムの他にアルミニウム合金を含むものとする。また、図1および図4の左側を前、右側を後といい、同じく上下を上下というものとする。さらに、図1および図4の紙面表側(図2、図3、図5および図6の左側)を左、これと反対側を後というものとする。 In the following description, the term “aluminum” includes aluminum alloys in addition to pure aluminum. Further, the left side of FIGS. 1 and 4 is referred to as the front, the right side is referred to as the rear, and the upper and lower sides are referred to as the upper and lower sides. Further, the front side of the paper surface of FIGS. 1 and 4 (left side of FIGS. 2, 3, 5 and 6) is the left side, and the opposite side is the rear side.
実施形態1
この実施形態は図1〜図3に示すものである。
This embodiment is shown in FIGS.
図1は密閉筐体内冷却装置の全体構成を示し、図2および図3はその要部の構成を示す。 FIG. 1 shows the overall configuration of a hermetically sealed casing cooling device, and FIGS. 2 and 3 show the configuration of the main part thereof.
図1において、密閉筐体内冷却装置は、内部に携帯電話の無線中継装置(図示略)が収納された密閉筐体(1)と、筐体(1)内に設けられかつ筐体(1)内の空気と筐体(1)外の空気とを熱交換させる熱交換装置(2)と、筐体(1)上に配置された太陽光発電パネル(3)と、太陽光発電パネル(3)で得られた電力を利用して筐体(1)内を冷却する冷却手段(4)とを備えている。筐体(1)の外面全体は白色塗膜(図示略)で覆われている。 In FIG. 1, a cooling device in a sealed housing includes a sealed housing (1) in which a mobile phone wireless relay device (not shown) is housed, and a housing (1) provided in the housing (1). A heat exchange device (2) for exchanging heat between the air inside and the air outside the housing (1), a solar power generation panel (3) disposed on the housing (1), and a solar power generation panel (3 And a cooling means (4) for cooling the inside of the housing (1) using the electric power obtained in (1). The entire outer surface of the housing (1) is covered with a white coating film (not shown).
熱交換装置(2)は、筐体(1)の前壁(1a)内面に取り付けられたケーシング(5)と、ケーシング(5)内に配置された熱交換器(6)と、筐体(1)内の空気をケーシング(5)内に取り入れて熱交換器(6)を通過させた後筐体(1)内に戻す筐体内空気送風機(7)と、筐体(1)外の空気をケーシング(5)内に取り入れて熱交換器(6)を通過させた後筐体(1)外に戻す筐体外空気送風機(8)とを備えている。 The heat exchange device (2) includes a casing (5) attached to the inner surface of the front wall (1a) of the casing (1), a heat exchanger (6) disposed in the casing (5), and a casing ( 1) The air inside the casing (5) is taken into the casing (5), passed through the heat exchanger (6), and then returned to the casing (1), and the air outside the casing (1) And an outside air blower (8) that returns the outside to the outside of the housing (1) after being taken into the casing (5) and passed through the heat exchanger (6).
ケーシング(5)の後壁(5a)上端部に、筐体(1)内に通じる筐体内空気入口(9)が形成され、後壁(5a)下部に、筐体(1)内に通じる筐体内空気出口(10)が形成されている。また、ケーシング(5)の前壁(5b)における筐体内空気出口(10)よりも下方の部分に、筐体(1)の前壁(1a)に形成された開口(12)を介して筐体(1)外に通じる筐体外空気入口(13)が形成され、前壁(5b)における筐体内空気入口(9)よりも下方の部分に、筐体(1)の前壁(1a)に形成された開口(14)を介して筐体(1)外に通じる筐体外空気出口(15)が形成されている。ケーシング(5)の後壁(5a)に、筐体(1)内の空気を筐体内空気入口(9)に導くフード(16)が後方突出状に取り付けられている。 An air inlet (9) in the housing that leads into the housing (1) is formed at the upper end of the rear wall (5a) of the casing (5), and a housing that leads into the housing (1) at the bottom of the rear wall (5a). A body air outlet (10) is formed. Further, the casing (5) has a front wall (5b) in a lower part than the air outlet (10) in the housing through an opening (12) formed in the front wall (1a) of the housing (1). The outside air inlet (13) that leads to the outside of the body (1) is formed, and the front wall (1a) of the housing (1) is formed on the front wall (5b) below the inside air inlet (9). A housing outside air outlet (15) communicating with the outside of the housing (1) through the formed opening (14) is formed. A hood (16) for guiding the air in the housing (1) to the air inlet (9) in the housing is attached to the rear wall (5a) of the casing (5) so as to protrude rearward.
熱交換器(6)は筐体内空気入口(9)と筐体外空気入口(13)との間の高さ位置に設けられており、筐体内空気入口(9)および筐体内空気出口(10)と通じる複数の筐体内空気通路(17)と、筐体外空気入口(13)および筐体外空気出口(15)と通じかつ筐体内空気通路(17)と独立した複数の筐体外空気通路(18)とを有している(図2および図3参照)。 The heat exchanger (6) is provided at a height between the air inlet (9) in the housing and the air inlet (13) outside the housing, and the air inlet (9) in the housing and the air outlet (10) in the housing. Multiple internal air passages (17) that communicate with the external air passage (17) and multiple external air passages (18) that communicate with the external air inlet (13) and the external air outlet (15) and are independent of the internal air passage (17) (Refer to FIG. 2 and FIG. 3).
図2および図3に示すように、熱交換器(6)は、左右方向に間隔をおいて並列状に配置された複数のアルミニウム製縦長方形状平板(20)と、隣り合う平板(20)間のすべての間隙の下端開口を1つおきに閉鎖するアルミニウム製下閉鎖部材(21)と、隣り合う平板(20)間のすべての間隙のうち下端開口が閉鎖されていない間隙の上端開口を閉鎖するアルミニウム製上閉鎖部材(22)と、隣り合う平板(20)間のすべての間隙のうち下端開口が閉鎖された間隙における後側(筐体内側)への開口を、下端部を除いて閉鎖するアルミニウム製第1後側閉鎖部材(23)(第1内側閉鎖部材)と、隣り合う平板(20)間のすべての間隙のうち下端開口が閉鎖された間隙における前側(筐体外側)への開口全体を閉鎖するアルミニウム製第1前側閉鎖部材(24)(第1外側閉鎖部材)と、隣り合う平板(20)間のすべての間隙のうち上端開口が閉鎖された間隙における前側への開口を、上端部を除いて閉鎖するアルミニウム製第2前側閉鎖部材(25)(第2外側閉鎖部材)と、隣り合う平板(20)間のすべての間隙のうち上端開口が閉鎖された間隙における後側への開口全体を閉鎖するアルミニウム製第2後側閉鎖部材(26)(第2内側閉鎖部材)と、隣り合う平板(20)間のすべての間隙に配置されたアルミニウム製インナーフィン(27)とを備えている。 As shown in FIGS. 2 and 3, the heat exchanger (6) includes a plurality of aluminum vertical rectangular flat plates (20) arranged in parallel in the left-right direction and adjacent flat plates (20). An aluminum lower closing member (21) that closes every other lower end opening of all gaps between them, and an upper end opening of a gap that is not closed among all the gaps between adjacent flat plates (20) The opening to the rear side (inside the casing) in the gap where the lower end opening is closed among all the gaps between the aluminum upper closing member (22) and the adjacent flat plate (20), except for the lower end To the front side (outside of the housing) in the gap where the lower end opening is closed among all the gaps between the aluminum first rear closing member (23) (first inner closing member) and the adjacent flat plate (20) to be closed Aluminum first front closure member (24) (first outer closure member) that closes the entire opening The second front closing member 25 made of aluminum (second outer closing) that closes the opening to the front side except the upper end portion in the gap where the upper end opening is closed among all the gaps between the adjacent flat plates 20 Member) and an aluminum second rear closing member (26) (second inner closing) that closes the entire rear opening in the gap in which the upper end opening is closed among all the gaps between the adjacent flat plates (20) Member) and aluminum inner fins (27) disposed in all the gaps between the adjacent flat plates (20).
平板(20)は両面にろう材層を有するアルミニウムブレージングシートからなり、下閉鎖部材(21)、上閉鎖部材(22)、第1および第2後側閉鎖部材(23)(26)、第1および第2前側閉鎖部材(24)(25)、ならびにインナーフィン(27)は、それぞれ隣り合う2枚の平板(20)間に配置されて平板(20)にろう付されている。 The flat plate (20) is made of an aluminum brazing sheet having a brazing filler metal layer on both sides. The lower closing member (21), the upper closing member (22), the first and second rear closing members (23) (26), the first The second front closing members (24) and (25) and the inner fin (27) are disposed between two adjacent flat plates (20) and brazed to the flat plate (20).
そして、隣り合う2枚の平板(20)、下閉鎖部材(21)、第1後側閉鎖部材(23)および第1前側閉鎖部材(24)により筐体内空気通路(17)が形成され、隣り合う2枚の平板(20)、上閉鎖部材(22)、第2前側閉鎖部材(25)および第2後側閉鎖部材(26)により筐体外空気通路(18)が形成されている。 The two adjacent flat plates (20), the lower closing member (21), the first rear closing member (23), and the first front closing member (24) form an in-chassis air passage (17). An outside air passage (18) is formed by the two flat plates (20), the upper closing member (22), the second front closing member (25), and the second rear closing member (26).
筐体内空気通路(17)の上端は開口しており、この開口(17a)がケーシング(5)の筐体内空気入口(9)に通じている。また、筐体内空気通路(17)は第1後側閉鎖部材(23)の下端よりも下方の部分において後方に開口しており、この開口(17b)がケーシング(5)の筐体内空気出口(10)に通じている。筐体外空気通路(18)の下端は開口しており、この開口(18a)がケーシング(5)の筐体外空気入口(13)に通じている。また、筐体外空気通路(18)は第2前側閉鎖部材(25)の上端よりも上方の部分において前方に開口しており、この開口(18b)がケーシング(5)の筐体外空気出口(15)に通じている。 The upper end of the air passage (17) in the housing is open, and the opening (17a) communicates with the air inlet (9) in the housing of the casing (5). Further, the air passage (17) in the housing opens rearward at a portion below the lower end of the first rear closing member (23), and this opening (17b) is the air outlet (internal housing) of the casing (5). 10). The lower end of the outside air passage (18) is open, and this opening (18a) communicates with the outside air inlet (13) of the casing (5). The outside air passage (18) opens forward in a portion above the upper end of the second front closing member (25), and this opening (18b) is the outside air outlet (15) of the casing (5). ).
インナーフィン(27)はコルゲート状であり、その波頭部および波底部が上下方向に伸びるように配置されている。筐体内空気通路(17)のインナーフィン(27)は開口(17b)よりも上方の部分に配置され、筐体外空気通路(18)のインナーフィン(27)は開口(18b)よりも下方の部分に配置されている。 The inner fin (27) has a corrugated shape, and is arranged such that the wave head and the wave bottom extend in the vertical direction. The inner fin (27) of the air passage (17) in the housing is disposed in a portion above the opening (17b), and the inner fin (27) of the air passage (18) in the housing is a portion below the opening (18b). Is arranged.
冷却手段(4)は、図1に示すように、頂壁(1b)を貫通して筐体(1)の内外に跨るように配置されかつ筐体(1)の内外で冷却流体を循環させるアルミニウム製や銅製の冷却流体循環管(30)と、筐体(1)外に配置されかつ冷却流体循環管(30)内で冷却流体を循環させるポンプ(31)とを備えており、ポンプ(31)が、太陽光発電パネル(3)で得られた電力により駆動されるようになっている。 As shown in FIG. 1, the cooling means (4) is disposed so as to pass through the top wall (1b) and straddle the inside and outside of the casing (1) and circulate the cooling fluid inside and outside the casing (1). A cooling fluid circulation pipe (30) made of aluminum or copper, and a pump (31) arranged outside the housing (1) and circulating the cooling fluid inside the cooling fluid circulation pipe (30). 31) is driven by the electric power obtained by the photovoltaic power generation panel (3).
冷却流体循環管(30)における筐体(1)内に存在する部分に蛇行状の受熱部(30a)が設けられるとともに筐体(1)外に存在する部分に蛇行状の放熱部(30b)が設けられ、受熱部(30a)に水平なプレート状のアルミニウム製受熱フィン(32)が、放熱部(30b)に垂直なプレート状のアルミニウム製放熱フィン(33)がそれぞれ複数取り付けられている。なお、冷却流体循環管(30)がアルミニウム製の場合、冷却流体としては、たとえば不凍液のようなアルミニウムに腐食が発生することのないものが用いられる。受熱部(30a)は、ケーシング(5)に取り付けられたフード(16)に臨んでいる。また、放熱部(30b)の上方に送風機(34)が配置され、この送風機(34)により放熱フィン(33)に風が送られるようになっている。送風機(34)も、太陽光発電パネル(3)で得られた電力により駆動されるようになっている。 A serpentine heat receiving portion (30a) is provided in a portion of the cooling fluid circulation pipe (30) existing in the housing (1), and a serpentine heat dissipation portion (30b) is provided in a portion existing outside the housing (1). A plurality of plate-shaped aluminum heat-receiving fins (32) that are horizontal to the heat-receiving portion (30a) and a plurality of plate-shaped aluminum heat-radiating fins (33) that are perpendicular to the heat-dissipating portion (30b) are attached. When the cooling fluid circulation pipe (30) is made of aluminum, a cooling fluid that does not cause corrosion such as antifreeze is used. The heat receiving portion (30a) faces the hood (16) attached to the casing (5). A blower (34) is disposed above the heat radiating section (30b), and wind is sent to the heat radiating fins (33) by the blower (34). The blower (34) is also driven by the electric power obtained by the solar power generation panel (3).
筐体内空気送風機(7)は、ケーシング(5)内における熱交換器(6)よりも上方でかつ筐体内空気入口(9)の近傍に、左右方向に並んで複数配置されている。筐体外空気送風機(8)は、ケーシング(5)内における熱交換器(6)よりも下方でかつ筐体外空気入口(13)の近傍に、左右方向に並んで複数配置されている。 A plurality of air blowers (7) in the housing are arranged side by side in the left-right direction above the heat exchanger (6) in the casing (5) and in the vicinity of the air inlet (9) in the housing. A plurality of outside case air blowers (8) are arranged side by side in the left-right direction below the heat exchanger (6) in the casing (5) and in the vicinity of the outside air inlet (13).
このような構成の密閉筐体内冷却装置において、昼間に筐体(1)内の温度が上限温度よりも高くなった場合、筐体内空気送風機(7)および筐体外空気送風機(8)が駆動される。筐体(1)内の高温空気は、フード(16)に導かれて筐体内空気入口(9)からケーシング(5)内に入り、熱交換器(6)の筐体内空気通路(17)を通過して筐体内空気出口(10)から筐体(1)内に戻される。一方、筐体(1)外の低温空気は、開口(12)および筐体外空気入口(13)からケーシング(5)内に入り、熱交換器(6)の筐体外空気通路(18)を通過して筐体外空気出口(15)および開口(14)から筐体(1)外に排出される。そして、熱交換器(6)において筐体内空気と筐体外空気とが熱交換をし、筐体内空気が冷却される。このとき、筐体内空気は筐体内空気通路(17)を下向きに流れ、筐体外空気は筐体外空気通路(18)を上向きに流れるので両者は対向流となり、熱交換効率が向上する。これと同時に、太陽光発電パネル(3)により得られた電力を用いてポンプ(31)および送風機(34)も駆動され、冷却流体が冷却流体循環管(30)内で循環させられるとともに、放熱フィン(33)に風が送られる。筐体内空気は、ケーシング(5)内に入る前に、冷却流体循環管(30)の受熱部(30a)の受熱フィン(32)間を通過し、冷却流体循環管(30)を流れる冷却流体に熱を奪われて冷却される。したがって、筐体内空気は、熱交換装置(2)で冷却される前に、冷却手段(4)により冷却されることになり、筐体内空気の冷却効率が向上する。筐体内空気から熱を奪った冷却流体は、放熱部(30b)に至り、送風機(34)により放熱フィン(33)に送られている風に放熱する。こうして、筐体(1)内の冷却が行われる。 In the airtight case cooling device having such a configuration, when the temperature in the case (1) becomes higher than the upper limit temperature in the daytime, the air blower in the case (7) and the air blower outside the case (8) are driven. The Hot air in the housing (1) is guided to the hood (16) and enters the casing (5) through the air inlet (9) in the housing, and passes through the air passage (17) in the housing of the heat exchanger (6). It passes through and returns from the air outlet (10) in the housing to the housing (1). On the other hand, the low-temperature air outside the housing (1) enters the casing (5) from the opening (12) and the air inlet (13) outside the housing, and passes through the air passage (18) outside the housing of the heat exchanger (6). Then, the air is discharged out of the housing (1) through the outside air outlet (15) and the opening (14). In the heat exchanger (6), the air inside the housing and the air outside the housing exchange heat, and the air inside the housing is cooled. At this time, since the air inside the housing flows downward through the air passage (17) inside the housing and the air outside the housing flows upward through the air passage outside the housing (18), they become counterflows, improving the heat exchange efficiency. At the same time, the pump (31) and the blower (34) are also driven using the electric power obtained by the photovoltaic power generation panel (3), and the cooling fluid is circulated in the cooling fluid circulation pipe (30) and also dissipates heat. Wind is sent to the fin (33). Before entering the casing (5), the air in the housing passes between the heat receiving fins (32) of the heat receiving portion (30a) of the cooling fluid circulation pipe (30) and flows through the cooling fluid circulation pipe (30). The heat is taken away and it is cooled. Therefore, the air in the housing is cooled by the cooling means (4) before being cooled by the heat exchange device (2), and the cooling efficiency of the air in the housing is improved. The cooling fluid deprived of heat from the air in the casing reaches the heat radiating section (30b) and radiates heat to the wind sent to the heat radiating fins (33) by the blower (34). Thus, the inside of the housing (1) is cooled.
太陽光発電パネル(3)の発電効率は夜間や冬期には低下するが、夜間や冬期においては筐体(1)外の温度も低くなるので、筐体(1)内の温度も低下し、熱交換装置(2)だけによっても筐体(1)内を十分に冷却することができる。 The power generation efficiency of the photovoltaic panel (3) decreases at night and in winter, but the temperature outside the case (1) also decreases at night and winter, so the temperature inside the case (1) also decreases, The housing (1) can be sufficiently cooled only by the heat exchange device (2).
実施形態2
この実施形態は図4に示すものである。
This embodiment is shown in FIG.
この実施形態の場合、冷却手段(40)は、頂壁(1b)を貫通して筐体(1)の内外に跨るように配置された複数の垂直状ヒートパイプ(41)と、ヒートパイプ(41)における筐体(1)外に存在する部分の後側に配置された送風機(42)とを備えており、送風機(42)が、太陽光発電パネル(3)で得られた電力により駆動されるようになっている。また、ヒートパイプ(41)における筐体(1)内に存在する部分の後側にも送風機(43)が配置され、この送風機(43)も、太陽光発電パネル(3)で得られた電力により駆動されるようになっている。 In the case of this embodiment, the cooling means (40) includes a plurality of vertical heat pipes (41) arranged so as to pass through the top wall (1b) and straddle the inside and outside of the housing (1), and heat pipes ( 41) and a blower (42) arranged on the rear side of the part existing outside the casing (1), and the blower (42) is driven by the electric power obtained by the photovoltaic power generation panel (3). It has come to be. In addition, a blower (43) is also arranged on the rear side of the portion of the heat pipe (41) that is present in the housing (1), and this blower (43) is also provided with electric power obtained by the photovoltaic power generation panel (3). It is driven by.
ヒートパイプ(41)は、筐体(1)内に存在する部分が蒸発部(41a)となっているとともに筐体(1)外に存在する部分が凝縮部(41b)となっている。ヒートパイプ(41)の蒸発部(41a)に水平なプレート状のアルミニウム製受熱フィン(44)が、凝縮部(41b)に水平なプレート状のアルミニウム製放熱フィン(45)がそれぞれ複数のヒートパイプ(41)に跨って取り付けられている。筐体(1)外の送風機(42)は放熱フィン(45)に風を送り、筐体(1)内の送風機(43)は受熱フィン(44)に風を送る。 In the heat pipe (41), a portion existing in the housing (1) is an evaporation portion (41a), and a portion existing outside the housing (1) is a condensing portion (41b). A plate-shaped aluminum heat receiving fin (44) horizontal to the evaporation section (41a) of the heat pipe (41) and a plate-shaped aluminum heat radiating fin (45) horizontal to the condensing section (41b) each have a plurality of heat pipes. It is mounted across (41). The blower (42) outside the housing (1) sends wind to the heat radiating fins (45), and the blower (43) inside the housing (1) sends wind to the heat receiving fins (44).
その他の構成は実施形態1の密閉筐体(1)内冷却装置と同じである。 Other configurations are the same as those of the cooling device in the sealed casing (1) of the first embodiment.
このような構成の密閉筐体内冷却装置において、昼間に筐体(1)内の温度が上限温度よりも高くなった場合、筐体内空気送風機(7)および筐体外空気送風機(8)が駆動される。筐体(1)内の高温空気と筐体(1)外の低温空気との熱交換は、実施形態1の場合と同様にして行われる。 In the airtight case cooling device having such a configuration, when the temperature in the case (1) becomes higher than the upper limit temperature in the daytime, the air blower in the case (7) and the air blower outside the case (8) are driven. The Heat exchange between the high-temperature air inside the casing (1) and the low-temperature air outside the casing (1) is performed in the same manner as in the first embodiment.
筐体内空気送風機(7)および筐体外空気送風機(8)の駆動と同時に、太陽光発電パネル(3)により得られた電力を用いて2つの送風機(42)(43)も駆動され、放熱フィン(45)および受熱フィン(44)に風が送られる。筐体内空気は、ケーシング(5)内に入る前に、ヒートパイプ(41)の蒸発部(41a)の受熱フィン(44)間を通過し、ヒートパイプ(41)の作動液が蒸発することにより熱を奪われて冷却される。したがって、筐体内空気は、熱交換装置(2)で冷却される前に、冷却手段(40)により冷却されることになり、筐体内空気の冷却効率が向上する。筐体内空気から熱を奪って蒸発した作動液は、凝縮部(41b)に至り、送風機(42)により放熱フィン(45)に送られている風に放熱して凝縮し、蒸発部(41a)に戻る。こうして、筐体(1)内の冷却が行われる。 Simultaneously with the driving of the air blower (7) inside the housing and the air blower (8) outside the housing, the two blowers (42) and (43) are also driven using the power obtained by the photovoltaic power generation panel (3), and the radiating fins Wind is sent to (45) and the heat receiving fin (44). The air in the housing passes between the heat receiving fins (44) of the evaporation part (41a) of the heat pipe (41) before entering the casing (5), and the working fluid in the heat pipe (41) evaporates. Deprived of heat and cooled. Therefore, the air in the housing is cooled by the cooling means (40) before being cooled by the heat exchange device (2), and the cooling efficiency of the air in the housing is improved. The working fluid that has evaporated heat from the air in the housing reaches the condensing part (41b), dissipates heat to the wind sent to the radiating fin (45) by the blower (42), condenses, and the evaporating part (41a) Return to. Thus, the inside of the housing (1) is cooled.
太陽光発電パネル(3)の発電効率は夜間や冬期には低下するが、夜間や冬期においては筐体(1)外の温度も低くなるので、筐体(1)内の温度も低下し、熱交換装置(2)だけによっても筐体(1)内を十分に冷却することができる。 The power generation efficiency of the photovoltaic panel (3) decreases at night and in winter, but the temperature outside the case (1) also decreases at night and winter, so the temperature inside the case (1) also decreases, The housing (1) can be sufficiently cooled only by the heat exchange device (2).
図5および図6は、実施形態1および2において、熱交換装置(2)に用いられる熱交換器の変形例を示す。 5 and 6 show a modification of the heat exchanger used in the heat exchange device (2) in the first and second embodiments.
図5および図6において、熱交換器(50)は、複数の熱交換器ユニット(50A)を左右方向に並べることにより形成されている。各熱交換器ユニット(50A)は、相互に間隔をおいて並列状に配置された複数の縦長方形状平板部(51a)と、隣り合う平板部(51a)の前側縁部どうしおよび後側縁部どうしを交互に一体に連結する連結板部(51b)とよりなり、かつ後側に開口した第1の間隙(54)と前側に開口した第2の間隙(55)とを交互に有するアルミニウム製蛇行板(51)、蛇行板(51)の前後両面をそれぞれ全体に覆うアルミニウム製前後両閉鎖板(52)(53)(外側閉鎖板および内側閉鎖板)、蛇行板(51)の第1間隙(54)の下端開口を閉鎖するアルミニウム製下閉鎖部材(56)、蛇行板(51)の第2間隙(55)の上端開口を閉鎖するアルミニウム製上閉鎖部材(57)、蛇行板(51)の第1および第2間隙(54)(55)に配置されたアルミニウム製インナーフィン(58)を備えている。 5 and 6, the heat exchanger (50) is formed by arranging a plurality of heat exchanger units (50A) in the left-right direction. Each heat exchanger unit (50A) includes a plurality of vertical rectangular flat plate portions (51a) arranged in parallel at intervals, and the front and rear edges of adjacent flat plate portions (51a). Aluminum having a connecting plate part (51b) for alternately connecting the parts alternately and having first gaps (54) opened at the rear side and second gaps (55) opened at the front side alternately Aluminum front and rear closing plates (52) and (53) (outer closing plate and inner closing plate) covering the entire front and rear surfaces of the meander plate (51) and the meander plate (51), the first of the meander plate (51) An aluminum lower closing member (56) for closing the lower end opening of the gap (54), an aluminum upper closing member (57) for closing the upper end opening of the second gap (55) of the meandering plate (51), and a meandering plate (51 ) First and second gaps (54), (55), and aluminum inner fins (58).
蛇行板(51)は両面にろう材層を有するアルミニウムブレージングシートから形成されている。前後両閉鎖板(52)(53)は、その左右両端部が前後方向内方に曲げられて蛇行板(51)の左右両端の平板部(51a)外面に係合させられた状態で、蛇行板(51)にろう付されている。後側閉鎖板(53)における蛇行板(51)の第1間隙(54)と対応する部分に、その下端から切り欠き(59)が形成され、前側閉鎖板(52)における蛇行板(51)の第2間隙(55)と対応する部分に、その上端から切り欠き(60)が形成されている。切り欠き(59)の下端は下閉鎖部材(56)により塞がれ、切り欠き(60)の上端は上閉鎖部材(57)により塞がれている。下閉鎖部材(56)、上閉鎖部材(57)およびインナーフィン(58)は、それぞれ蛇行板(51)の隣り合う2つの平板部(51a)間に配置されて平板部(51a)にろう付されている。 The meander plate (51) is formed of an aluminum brazing sheet having a brazing filler metal layer on both sides. The front and rear closing plates (52) and (53) are meandered with their left and right ends bent inward in the front and rear direction and engaged with the outer surfaces of the flat plate portions (51a) at both left and right sides of the meandering plate (51). It is brazed to the plate (51). A notch (59) is formed from the lower end of a portion corresponding to the first gap (54) of the meandering plate (51) in the rear side closing plate (53), and the meandering plate (51) in the front side closing plate (52). A notch (60) is formed from the upper end of the portion corresponding to the second gap (55). The lower end of the notch (59) is closed by the lower closing member (56), and the upper end of the notch (60) is closed by the upper closing member (57). The lower closing member (56), the upper closing member (57), and the inner fin (58) are disposed between two adjacent flat plate portions (51a) of the meandering plate (51) and brazed to the flat plate portion (51a). Has been.
そして、蛇行板(51)の第1間隙(54)を形成する隣り合う2つの平板部(51a)、これら2つの平板部(51a)の前側縁部どうしを一体に連結する連結板部(51b)、後側閉鎖板(53)および下閉鎖部材(56)により筐体内空気通路(61)が形成され、蛇行板(51)の第2間隙(55)を形成する隣り合う2つの平板部(51a)、これら2つの平板部(51a)の後側縁部どうしを一体に連結する連結板部(51b)、前側閉鎖板(52)および上閉鎖部材(57)により筐体外空気通路(62)が形成されている。
筐体内空気通路(61)の上端は開口しており、この開口(61a)がケーシング(5)の筐体内空気入口(9)に通じている。また、筐体内空気通路(61)は後側閉鎖板(53)の切り欠き(59)の部分で後方に開口しており、この開口(61b)がケーシング(5)の筐体内空気出口(10)に通じている。筐体外空気通路(62)の下端は開口しており、この開口(62a)がケーシング(5)の筐体外空気入口(13)に通じている。また、筐体外空気通路(62)は前側閉鎖板(52)の切り欠き(60)の部分で前方に開口しており、この開口(62b)がケーシング(5)の筐体外空気出口(15)に通じている。
Then, two adjacent flat plate portions (51a) forming the first gap (54) of the meandering plate (51), and a connecting plate portion (51b) for connecting the front edge portions of the two flat plate portions (51a) together. ), The rear closing plate (53) and the lower closing member (56) form an air passage (61) in the housing, and two adjacent flat plate portions (second plate portion (55) of the meandering plate (51) ( 51a), a connecting plate portion (51b) for integrally connecting the rear edge portions of these two flat plate portions (51a), a front closing plate (52), and an upper closing member (57) to provide an outside air passage (62) Is formed.
The upper end of the air passage (61) in the housing is open, and the opening (61a) communicates with the air inlet (9) in the housing of the casing (5). Further, the air passage (61) in the housing opens rearward at the notch (59) of the rear closing plate (53), and this opening (61b) is the air outlet (10) in the housing of the casing (5). ). The lower end of the outside air passage (62) is open, and this opening (62a) communicates with the outside air inlet (13) of the casing (5). The outside air passage (62) is opened forward at the notch (60) portion of the front closing plate (52), and this opening (62b) is the outside air outlet (15) of the casing (5). Leads to.
インナーフィン(58)はコルゲート状であり、その波頭部および波底部が上下方向に伸びるように配置されている。筐体内空気通路(61)のインナーフィン(58)は開口(61b)よりも上方の部分に配置され、筐体外空気通路(62)のインナーフィン(58)は開口(62b)よりも下方の部分に配置されている。 The inner fin (58) has a corrugated shape and is disposed such that the wave head and the wave bottom extend in the vertical direction. The inner fin (58) of the air passage (61) in the housing is disposed at a portion above the opening (61b), and the inner fin (58) of the air passage (62) outside the housing is a portion below the opening (62b). Is arranged.
(1):密閉筐体
(2):熱交換装置
(3):太陽光発電パネル
(4)(40):冷却手段
(5):ケーシング
(6):熱交換器
(7):筐体内空気送風機
(8):筐体外空気送風機
(9):筐体内空気入口
(10):筐体内空気出口
(13):筐体外空気入口
(15):筐体外空気出口
(17):筐体内空気通路
(17a)(17b):開口
(18):筐体外空気通路
(18a)(18b):開口
(20):平板
(21):下閉鎖部材
(22):上閉鎖部材
(23):第1後側閉鎖部材(第1内側閉鎖部材)
(24):第1前側閉鎖部材(第1外側閉鎖部材)
(25):第2前側閉鎖部材(第2外側閉鎖部材)
(26):第2後側閉鎖部材(第2内側閉鎖部材)
(27):インナーフィン
(30):冷却流体循環管
(30a):受熱部
(30b):放熱部
(31):ポンプ
(32):受熱フィン
(33):放熱フィン
(34):送風機
(41):ヒートパイプ
(41a):蒸発部
(41b):凝縮部
(42):送風機
(50):熱交換器
(50A):熱交換器ユニット
(51):蛇行板
(51a):平板部
(51b):連結板部
(52)(53):閉鎖板
(54):第1間隙
(55):第2間隙
(56):下閉鎖部材
(57):上閉鎖部材
(58):インナーフィン
(61):筐体内空気通路
(61a)(61b):開口
(62):筐体外空気通路
(62a)(62b):開口
(1): Sealed enclosure
(2): Heat exchange device
(3): Solar power generation panel
(4) (40): Cooling means
(5): Casing
(6): Heat exchanger
(7): Air blower in the housing
(8): Outside air blower
(9): Inlet air inlet
(10): Air outlet in the housing
(13): Outside air inlet
(15): Outside air outlet
(17): Internal air passage
(17a) (17b): Opening
(18): Outside air passage
(18a) (18b): Opening
(20): Flat plate
(21): Lower closing member
(22): Upper closing member
(23): First rear closing member (first inner closing member)
(24): First front closing member (first outer closing member)
(25): Second front closing member (second outer closing member)
(26): second rear closing member (second inner closing member)
(27): Inner fin
(30): Cooling fluid circulation pipe
(30a): Heat receiving part
(30b): Heat dissipation part
(31): Pump
(32): Heat receiving fin
(33): Radiating fin
(34): Blower
(41): Heat pipe
(41a): Evaporating section
(41b): Condensing part
(42): Blower
(50): Heat exchanger
(50A): Heat exchanger unit
(51): Meander board
(51a): Flat plate
(51b): Connecting plate
(52) (53): Closure plate
(54): 1st gap
(55): Second gap
(56): Lower closing member
(57): Upper closing member
(58): Inner fin
(61): Internal air passage
(61a) (61b): Opening
(62): Outside air passage
(62a) (62b): Opening
Claims (15)
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JP2003432145 | 2003-12-26 | ||
JP2004362444A JP2005210088A (en) | 2003-12-26 | 2004-12-15 | Cooling device in closed cabinet |
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JP2005210088A true JP2005210088A (en) | 2005-08-04 |
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JP2004362444A Pending JP2005210088A (en) | 2003-12-26 | 2004-12-15 | Cooling device in closed cabinet |
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CN106659096A (en) * | 2017-02-23 | 2017-05-10 | 湖南中科泰通热能科技发展有限公司 | Heat exchange unit used for electrical equipment |
CN107027273A (en) * | 2017-05-08 | 2017-08-08 | 广东工业大学 | A kind of rack overhead type heat-exchanger rig |
CN107027273B (en) * | 2017-05-08 | 2023-04-07 | 广东工业大学 | Overhead heat transfer device of rack |
CN108633231A (en) * | 2018-06-28 | 2018-10-09 | 芜湖中淇节能科技有限公司 | A kind of radiator of energy-saving and high efficient electromechanical equipment |
KR101995512B1 (en) * | 2019-03-22 | 2019-07-02 | 엘제이테크 주식회사 | Coller for industrial apparatus |
CN110671283A (en) * | 2019-09-25 | 2020-01-10 | 常州优谷新能源科技股份有限公司 | Gravity heat pipe type cooling device for wind driven generator |
CN111698889A (en) * | 2020-07-10 | 2020-09-22 | 陈海鑫 | High-efficient heat abstractor |
CN112153876A (en) * | 2020-10-21 | 2020-12-29 | 江苏勒图智能科技有限公司 | Soaking plate heat exchanger |
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